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I was testing out the mmultP function from repa-algorithms-3.2.1.1 with the following code (a tad condensed here for brevity):

import Data.Array.Repa hiding            (map)
import Data.Array.Repa.Algorithms.Matrix (mmultP)

import Control.Monad                     (replicateM)
import Control.Arrow                     ((&&&))
import System.Random.MWC                 (initialize, uniformR)
import Control.Monad.ST                  (runST)
import Data.Vector.Unboxed               (singleton)
import Data.Word                         (Word32)

-- Create a couple of dense matrices
genRnds :: Word32 -> [Double]
genRnds seed = runST $ do
    gen <- initialize (singleton seed)
    replicateM (1000 ^ 2) (uniformR (0, 1) gen)

(arr, brr) = head &&& last $ map (fromListUnboxed (Z :. 1000 :. 1000 :: DIM2) . genRnds) [1, 100000]

-- mmultP test
main :: IO ()
main = mmultP arr brr >>= print

and as specified here, compiled using

ghc mmultTest.hs -Odph -rtsopts -threaded -fno-liberate-case -funfolding-use-threshold1000 -funfolding-keeness-factor1000 -fllvm -optlo-O3 -fforce-recomp

Here's the sequential run in the threaded runtime:

$ time ./mmultTest +RTS -K100M > /dev/null
real    0m10.962s
user    0m10.790s
sys     0m0.161s

and here's one using 4 cores (running on a four-core MacBook Air):

$ time ./mmultTest +RTS -N4 -K100M > /dev/null
real    0m13.008s
user    0m18.591s
sys     0m2.067s

Anyone have any intuition as to what's happening here? I also get slower-than-sequential performance for -N2 and -N3; each core seems to add some additional time.

Note that I do observe some minor gains from parallelism on some hand-rolled Repa matrix multiply code.

UPDATE:

Puzzling; I replaced main with

mmultBench :: IO ()
mmultBench  = do 
   results <- mmultP arr brr 
   let reduced = sumAllS results 
   print reduced

and removed the dependency on mwc-random:

(arr, brr) = head &&& last $ map (fromListUnboxed (Z :. 1000 :. 1000 :: DIM2)) (replicate 2 [1..1000000])

A Criterion benchmark with the runtime options -N1 -K100M yields:

mean: 1.361450 s, lb 1.360514 s, ub 1.362915 s, ci 0.950
std dev: 5.914850 ms, lb 3.870615 ms, ub 9.183472 ms, ci 0.950

and -N4 -K100M gives me:

mean: 556.8201 ms, lb 547.5370 ms, ub 573.5012 ms, ci 0.950
std dev: 61.82764 ms, lb 40.15479 ms, ub 102.5329 ms, ci 0.950

Which is a lovely speedup. I would almost think that the previous behaviour was due to writing the resulting 1000x1000 array to stdout, but as I mentioned, I do observe parallelism gains there if I swap in my own matrix multiply code. Still scratching my head.

share|improve this question
    
Which GHC version? –  Don Stewart Jul 31 '12 at 14:07
    
Using GHC 7.4.1. –  jtobin Jul 31 '12 at 14:09
    
What do you get when using 3 cores? –  John L Jul 31 '12 at 15:04
    
Also slower-than-sequential, but faster than -N4. Same situation for -N2. –  jtobin Jul 31 '12 at 15:39

2 Answers 2

up vote 1 down vote accepted

1) Printing the matrix to stdout will make the program IO bound. Any speedup figures recorded in this situation will be lies.

2) There are no 4 core MacBook Airs. They are all 2 core, with 2 hyper-threads per core. Only 2 threads can actually run at a time. Any speedup with > -N2 will be due to latency hiding -- the second hyper-thread on a core can run while the first is stalled on cache-miss.

share|improve this answer
    
Thanks, that was my suspicion. Swapping in the hand-rolled code resulted in slower performance than mmultP across-the-board, but it did yield slightly quicker times under -N2 and -N4 than w/-N1. That was the source of my confusion. –  jtobin Aug 6 '12 at 11:37

This does seem strange, but maybe you are just making the usual payment for parallelism but not reaping the benefits? --So it's akin to parallelizing with absurdly unbalanced loads?

It seems like something more must be wrong. What struck me, though -- and it might give a partial explanation of your results -- is that you are only using one repa combinator, mmultP. The framework hardly gets a chance! If I complicate the matter with a sprinking of zipWith, foldAllP etc. -- e.g.

main :: IO ()
main =  arr `xxx` brr >>= foldAllP (+) 0 >>= print where
   xxx arr brr = R.zipWith (+) <$> complicated arr <*> complicated brr
   complicated = mmultP brr >=> mmultP arr >=> mmultP brr >=> mmultP arr

Then with my two-core jalopy, I get exactly the two-core-parallelizer's dream:

 $ time ./mmmult +RTS -K200M  -N2
 6.2713897715510016e16

 real   0m8.742s
 user   0m16.176s
 sys    0m0.444s

 $ time ./mmmult +RTS -K200M  
 6.2713897715512584e16

 real   0m15.214s
 user   0m14.970s
 sys    0m0.239s
share|improve this answer
    
Yeah, I get that nice speedup from your code as well. I actually almost fooled myself when updating this question, because I had done some parallel reductions with sumAllP et al that improved my times under -N4 nicely; it seems like I'm really just not getting the desired utilisation on mmultP. Do you get similar times using the simple main = mmultP arr brr >>= print from my example? –  jtobin Aug 2 '12 at 23:32
    
Yes, my result was akin to yours for the original module. But the more complicated I made main the better my results, as least as far as parallelizing goes. –  applicative Aug 3 '12 at 1:11

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